Lighting apparatus and light guide

ABSTRACT

According to one embodiment, a lighting apparatus includes a light source which includes a light emitting surface, and a light guide provided to be coaxial with an axis which extends along a direction perpendicular to the light emitting surface. The light guide includes: an incident plane facing the light emitting surface; an outer circumferential surface configured to protrude in a direction extending away from the light source so as to surround the axis from an outer periphery of the incident surface and so as to totally reflect light from the light source which is made to enter the light guide from the incident surface; and a hollow part provided at a position distant in the axis direction from the incident surface. The hollow part includes a first light diffusing surface parallel to an axis along which the light totally reflected on the outer circumferential surface is led.

CROSS-REFERENCE TO RELATED APPLICATION

This application is based upon and claims the benefit of priority fromprior Japanese Patent Application No. 2013-123101, filed Jun. 11, 2013;the entire contents of which are incorporated herein by reference.

FIELD

Embodiments described herein relate generally to a lighting apparatusand a light guide.

BACKGROUND

In the field of LED lamps for general-purpose lighting, spreading andshining of light are demanded to follow (retrofit) those of incandescentlight bulbs. Specifically, there is a strong demand for spreading lightover a wide range from a point light source positioned in a center partof a glass globe, as in a clear electric light bulb.

However, LEDs have strong directivity, and a light distribution angle ofan LED lamp is therefore as narrow as approximately 120 degrees if LEDsare used directly as a light source.

Hence, an LED lamp is commonly known which scatters light emitted froman LED over a wide range by using a light guide column. A conventionallight guide column is arranged coaxially along an optical axis of anLED.

The light guide column comprises an incident plane and a tip endpositioned on a side opposite to the incident plane. A scattering memberis provided at the tip end of the light guide column.

When light emitted from LEDs is made to enter the incident plane of thelight guide column, the incident light is led to the scattering memberthrough the inside of the light guide column and penetrates thescattering member while the incident light is simultaneously reflectedon the scattering member. Thus, the light which has penetrated and beenscattered by the light guide column is emitted and diffused from the tipend of the light guide column.

A distribution angle of an LED lamp using a light guide column asdescribed above increases as the number of times light is scattered by ascattering member increases.

However, when a scattering member is used, a part of scattered lightreturns in a direction of a light emitting module through a light guidecolumn, and is absorbed by the light emitting module. In a commonscattering member, internal scattering particles slightly absorb light.Therefore, when scattering takes place a greater number of times, lightis absorbed at a greater ratio by a light emitting module and thescattering member.

As a result, light spreads in an improved manner while luminaireefficiency of a whole LED lamp deteriorates. There thus is still marginfor improvement to effectively use the light emitted from LEDs.

Accordingly, development of a lighting apparatus is demanded which canachieve a wide light distribution and can simultaneously improve theluminaire efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view showing a partial cross section of an LEDlamp according to the first embodiment;

FIG. 2 is a sectional view showing a positional relationship between alight guide member and a COB-type light emitting module in the firstembodiment;

FIG. 3 is a sectional view of a light emitting module used in the firstembodiment;

FIG. 4 is a perspective view of a cylindrical light guide columnmentioned in descriptions of a first light diffusing surface in thefirst embodiment;

FIG. 5 is a graph showing a result of performing a ray-tracingsimulation of whole light fluxes emitted from an outer circumferentialsurface of a cylindrical light guide column in the first embodiment;

FIG. 6 is a diagram showing paths of light rays which have entered alight guide member from an incident plane in the first embodiment;

FIG. 7 is a side view of an LED lamp according to the second embodiment;

FIG. 8 is a side view showing a partial cross section of a light guidemember used in the second embodiment;

FIG. 9 is a sectional view of a tip end of the light guide member usedin the second embodiment;

FIG. 10 is a sectional view of a light diffuser used in the secondembodiment;

FIG. 11 is a diagram showing paths of light rays which have beenreflected on an outer circumferential surface of the light guide memberin the second embodiment;

FIG. 12 is a chart showing the distribution of light which haspenetrated the light guide member in the second embodiment;

FIG. 13 is a side view of an LED lamp according to the third embodiment;

FIG. 14 is a sectional view of a light guide member used in the thirdembodiment; and

FIG. 15 is a diagram showing paths of light rays which have entered thelight guide member from the incident plane in the third embodiment.

DETAILED DESCRIPTION

According to one embodiment, a lighting apparatus comprises a lightsource which comprises a light emitting surface, and a light guidemember provided to be coaxial with an axis which extends through acentroid of the light emitting surface along a direction perpendicularto the light emitting surface. The light guide member comprises anincident plane facing the light emitting surface, an outercircumferential surface configured to protrude in a direction extendingaway from the light source so as to surround the axis from an outerperipheral edge of the incident plane and so as to totally reflect lightfrom the light source which has been made to enter the light guidemember from the incident plane, and a hollow part provided at a positiondistant along an axis direction of the axis from the incident plane. Thehollow part comprises a first light diffusing surface parallel to anaxis along which the light totally reflected on the outercircumferential surface is led.

Various embodiments will be described hereinafter with reference to theaccompanying drawings.

First Embodiment

Hereinafter, the first embodiment will be described with reference toFIGS. 1, 2, 3, 4, 5, and 6.

FIG. 1 is a side view showing a partial cross section of an LED lamp asan example of a lighting apparatus. FIG. 2 is a sectional view showing apositional relationship between a light guide member and a COB-typelight emitting module. FIG. 3 is a sectional view of the light emittingmodule. FIG. 4 is a perspective view of a cylindrical light guide columnmentioned in descriptions of a first light diffusing surface. FIG. 5 isa graph showing a result of performing a simulation of whole lightfluxes emitted from an outer circumferential surface of the cylindricallight guide column. FIG. 6 is a diagram showing paths of rays of lightwhich is made to enter the cylindrical light guide column from anincident plane.

FIG. 1 discloses an LED lamp 1 having, for example, a shape similar to aclear-type chandelier bulb. The LED lamp 1 comprises, as maincomponents, a lamp body 2, a globe 3, a COB (chip on board) type lightemitting module 4, a lighting circuit 5, and a light guide 6.

The lamp body 2 is made of a metal material having more excellentthermal conductivity than iron, such as aluminum, and functions also asa heat radiator. The lamp body 2 is a component having an approximatelycircular columnar shape, which has one end and another end, and isshaped to have a diameter which increases gradually toward the other endfrom the one end.

A base 7 having an E shape is attached to the one end of the lamp body2. A recess 8 is formed in a central part of the other end of the lampbody 2. The recess 8 is positioned on the center axis of the lamp body2. An inner circumferential surface of the recess 8 is finished, forexample, into a white light diffusing surface 8 a.

The globe 3 is formed in an approximately circular conical shape byusing, for example, a transparent synthetic resin material such asacryl, or clear glass. The globe 3 comprises a top part 3 a having aspherical shape, and an open end part 3 b which faces the top part 3 a.The open end part 3 b defines the maximum diameter of the globe 3 and isconnected coaxially with the other end of the lamp body 2.

According to the present embodiment, the lamp body 2 comprising the base7 and the globe 3 form, in cooperation with each other, an outer shapesimilar to a chandelier bulb.

The globe 3 is not limited only to a conical shape but may have asemispherical shape. Further, the globe 3 may alternatively be made of,for example, a milk-white synthetic resin material to make the globe 3light-diffusible.

The light emitting module 4 is a light source of the LED lamp 1, and iscontained in the recess 8 of the lamp body 2. As shown in FIG. 3, thelight emitting module 4 comprises an insulating substrate 10, aplurality of light emitting diodes 11, a frame 12, and a sealingmaterial 13.

The insulated substrate 10 is a square whose edges each have, forexample, a length of 3.2 mm and is fixed to the bottom surface of therecess 8 by means of screwing or the like. Further, the insulatingsubstrate 10 is thermally connected to the bottom surface (lamp body 2)of the recess 8, for example, by thermally conductive grease.

The light emitting diodes 11 are an example of a semiconductor lightemitting device, and are arrayed in a matrix on the insulating substrate10. The frame 12 is adhered to an outer circumferential part of theinsulating substrate 10, and surrounds the light emitting diodes 11.

The sealing material 13 is a transparent or translucent resin materialcontaining fluorescent particles. The sealing agent 13 is filled in aregion surrounded by the frame 12 so as to cover all the light emittingdiodes 11.

The fluorescent particles contained in the sealing material 13 areexcited by light emitted from the light emitting diodes 11, and emitlight of a complementary color for light emitted from the light emittingdiodes 11. As a result, the light emitted from the light emitting diodes11 and the light emitted from the fluorescent particles are mixed insidethe sealing material 13, forming white light. The white light isinjected from a surface of the sealing agent 13.

Therefore, the surface of the sealing material 13 configures arectangular light emitting surface 14 which emits planar light.According to the present embodiment, the light emitted from the lightemitting surface 14 is visible light having a wavelength from 400 nm to800 nm although the wave length of light is not limited to thiswavelength.

As shown in FIGS. 1 and 2, the light emitting module 4 has a straightoptical axis O1 as its axis. The optical axis O1 extends through thecenter of the light emitting surface 14 or the vicinity of the center ina direction perpendicular to the light emitting surface 14.

The center of the light emitting surface 14 corresponds to the centroidof the light emitting surface 14. Therefore, the center may be out of aregion just on the light emitting surface 14 (hereafter, the phrase “ona surface” is intended to mean “part of a surface”). For example, wherea light emitting surface has an annular shape, the center thereof is thecenter of an outer circle or an inner circle defining the annular shapeof the light emitting surface, and does not exist on the light emittingsurface.

Light distribution of the light emitted from the light emitting surface14 is nearly symmetrical about the optical axis O1. Specifically, thelight emitting surface 14 has a light distribution close to, forexample, a Lambertian type although the light distribution is notlimited to this type.

Further, in the present embodiment, the regular direction of the opticalaxis O1 is defined as a direction of light extracted along the opticalaxis O1 from the light emitting surface 14. The direction of lightextracted along the optical axis O1 is a direction at a distributionangle of 0 degrees, and corresponds to an outward normal vector towardthe globe 3 from the light emitting surface 14.

The lighting circuit 5 is a component for supplying a constant currentto the light emitting module 4. The lighting circuit 5 is containedinside the lamp body 2, and is electrically connected to the base 7 andthe light emitting diodes 11.

As shown in FIG. 1, the light guide 6 is contained inside the globe 3 soas to face the light emitting surface 14 of the light emitting module 4.The light guide 6 of the present embodiment comprises a light guidecolumn 16 and a light diffuser 17.

The light guide column 16 is an example of a light guide member and isprovided to be coaxial with the optical axis O1. Further, the lightguide column 16 has a shape which is rotationally symmetrical about theoptical axis O1. The term “rotationally symmetrical” herein means that ashape of an object rotated about the optical axis O1 corresponds to theshape of the object in an original position (not rotated) while therotated angle is less than 360 degree. In the present embodiment, thelight guide column 16 has a straight circular columnar shape.

The light guide column 16 is made of, for example, transparent acryl.Acryl has a refractive index n of 1.49. The light guide column 16 is notlimited to acryl but may be a transparent material such as polycarbonateor glass which allows visible light to penetrate. There is no particularlimitation to the material of the light guide column 16.

As shown in FIGS. 1 and 2, the light guide column 16 comprises anincident plane 18, an outer circumferential surface 19, a tip endsurface 20, and a hollow part 21.

The incident plane 18 is a flat circular surface perpendicular to theoptical axis O1, and faces the light emitting surface 14 of the lightemitting module 4. The incident plane 18 has a larger shape than thelight emitting surface 14. Further, the incident plane 18 includes apoint O7 at which the incident plane intersects the optical axis O1.

The outer circumferential surface 19 extends in a direction extendingaway from the light emitting module 4 so as to coaxially surround theoptical axis O1 from an outer peripheral edge of the incident plane 18.The outer circumferential surface 19 extends in parallel with theoptical axis O1. The outer circumferential surface 19 can function as atotal reflection surface which totally reflects the light of the lightemitting diodes 11 made to enter the light guide column 16 from theincident plane 18. The outer circumferential surface 19 as a totalreflection surface is finished into a smooth glossy surface.

A critical angle θ_(C) which achieves total reflection, in relation tothe outer circumferential surface 19, can be expressed as follows byusing the refractive index n of the light guide column 16.

$\begin{matrix}{\theta_{C} = {\sin^{- 1}\left( \frac{1}{n} \right)}} & (1)\end{matrix}$

In the present embodiment, the light guide column 16 is made of acryl,and the critical angle θ_(C) is 42.2.

The tip end surface 20 is a flat surface perpendicular to the opticalaxis O1, and is positioned in a side opposite to the incident plane 18along the axial direction of the optical axis O1.

As shown in FIG. 2, the hollow part 21 is formed in the tip end side ofthe light guide column 16, and is distant from the incident plane 18along the axial direction of the optical axis O1. The hollow part 21 hasa cylindrical shape coaxial with the optical axis O1 and is open in thetip surface 20 of the light guide column 16.

An inner surface 23 which defines the hollow part 21 comprises acircumferential surface 24 surrounding the optical axis O1, and a bottomsurface 25 perpendicular to the optical axis O1. The circumferentialsurface 24 comprises a first light diffusing surface 26 parallel to theoptical axis O1. The first light diffusing surface 26 is continuous tothe tip end surface 20 of the light guide column 16. The bottom surface25 faces the incident plane 18 at the bottom of the hollow part 21.

Further, the inner surface 23 of the hollow part 21 comprises adiffusion region 27 which connects the first light diffusing surface 26to the bottom surfaces 25. The diffusion region 27 is defined by atapered surface inclined so as to gradually approach the optical axis O1from the first light diffusing surface 26 toward the bottom surface 25.

The inner surface 23 of the hollow part 21 including the first lightdiffusing surface 26 is made of a rough surface having lightdiffusibility. The rough surface is formed by so-called sandblasting ofspraying, for example, a polishing material having a grain diameter of100 μm to the inner surface 23. In this manner, much unevenness isformed in the inner surface 23, and a white surface which has lightreflectivity without using a scattering member can be obtained.

The measure of making the inner surface 23 light-diffusible is notlimited to sandblasting. For example, a coating material includingparticles (scattering particles) for scattering light may be coated onthe inner surface 23. The film thickness of the coating material coatedon the inner surface 23 may be so thin as to allow light to penetrate.

Specifically, absorption of light by the coated coating material isnegligible insofar as the film thickness of a coating material is 1 mmor less. In this case, scattering particles exist only on surfaces of anobject, and scattering particles are not distributed within the volumeof the object, unlike the scattering member. In actual practice, whenlight penetrates the scattering member, absorption of light is notnegligible.

FIG. 2 shows a cross sectional shape of the hollow part 21 where thelight guide column 16 is cut along a plane including the axis of theoptical axis O1. In FIG. 2, the distance from the first light diffusingsurface 26 to the optical axis O1 along a direction perpendicular to theoptical axis O1 is expressed as R₁, and the distance from the outercircumferential surface 19 of the light guide column 16 to the opticalaxis O1 along a direction perpendicular to the optical axis O1 isexpressed as R2. The length of the first light diffusing surface 26along the axial direction of the optical axis O1 is expressed as L. Thefirst light reflex surface 26 satisfies a relationship below.L≧2(R ₂ −R ₁)tan θ_(C)  (2)

For example, where the distance R₂ is 2.0 mm, the distance R₁ is 1.3 mm,and the length L is 3.4 mm, a relationship below exists.L=3.4≧2(R ₂ −R ₁)tan θ_(C)=1.3  (3)

Further, the maximum distance H from the tip end of the first lightdiffusing surface 26 which reaches the tip end surface 20 of the lightguide column 16 to the light emitting surface 14 satisfies arelationship below, where R₃ is the distance to the optical axis O1 froman end point A6 on the peripheral edge of the light emitting surface 14along the direction perpendicular to the optical axis O1.H≧(2R ₂ +R ₃ −R ₁)tan θ_(C)  (4)

In the present embodiment, the maximum distance H is 22.3 mm.

The distance R₃ takes a value which varies depending on the position ofthe cross section extending through the light emitting surface 14 unlessthe light emitting surface 14 has a circular shape or an annular shape.

Hence, the following expression is defined where C is the area of thelight emitting surface 14.

$\begin{matrix}{R_{3} = \sqrt{\frac{C}{\pi}}} & (5)\end{matrix}$

According to the present embodiment, R₃ is 1.8 mm. Therefore, thepresent embodiment gives an expression below, and thus satisfies theexpression 4 above.H=22.3≧(2R ₂ +R ₃ −R ₁)tan θ_(C)=4.1  (6)

As shown in FIGS. 1 and 2, the light diffuser 17 of the light guide 6 ispartially contained in the hollow part 21 of the light guide column 16.The light diffuser 17 is made of, for example, transparent acryl, thoughis not limited to acryl. Any material can be appropriately selected andused insofar as the material allows visible light to penetrate.

As shown in FIG. 2, the light diffuser 17 comprises a post part 28 and aflange part 29. The post part 28 is a solid cylindrical component havinga smaller diameter than the hollow part 21, and comprises a second lightdiffusing surface 30 parallel to the optical axis O1, and a flat endsurface 31 perpendicular to the optical axis O1.

The flange part 29 is formed coaxially in the end opposite to the endsurface 31 of the post part 28, and protrudes in radial directions ofthe post part 28. The surface of the flange part 29 forms the thirdlight diffusing surface 32 which bulges into a spherical shape.

The flange part 29 is fixed to the tip end surface 20 of the light guidecolumn 16 by means of adhesion. By this fixture, the post part 28 of thelight diffuser 17 is held coaxially inside the hollow part 21, and anopen end of the hollow part 21 is closed by the flange part 29. Further,an annular air layer 33 is provided between the first light diffusingsurface 26 of the hollow part 21 and the second light diffusing surface30 of the light diffuser 17.

According to the present embodiment, the second light diffusing surface30 of the light diffuser 17, the end surface 31, and the third lightdiffusing surface 32 are configured by rough surfaces which arelight-diffusible. The rough surfaces are formed by so-calledsandblasting of spraying, for example, a polishing material having agrain diameter of 100 μm to the surface of the light diffuser 17.

The measure of making the light diffuser 17 light-diffusible is notlimited to sandblasting. For example, a coating material includingparticles for scattering light may be coated on the surface of the lightdiffuser 17. At this time, the film thickness of the coating material tobe coated on the inner surface 23 may be so thin as to allow light topenetrate.

An end of the light guide column 16 having such a light diffuser 17,which comprises the incident plane 18, is held in the hollow part 8 ofthe lamp body 2. Therefore, the end of the light guide column 16 issurrounded by the light diffusing surface 8 a of the hollow part 8, andthe tip end of the light guide column 16 including the light diffuser 17is positioned in the central part of the globe 3.

Light emitted from the light emitting surface 14 of the light emittingmodule 4 enters the inside of the light guide column 16 through theincident plane 18. Specifically, as illustrated by a light ray A in FIG.2, the light toward the hollow part 21 along the optical axis O1 fromthe end point A6 on the peripheral edge of the light emitting surface 14is diffused on and penetrates the diffusion region 27 of the hollow part21, and thereafter enters the end surface 31 of the light diffuser 17.

Light which is made to enter the light diffuser 17 is diffused on andpenetrates the third light diffusing surface 32, and thereafter travelsin the positive direction of the optical axis O1. In other words, thelight diffuser 17 performs a function to diffuse light toward thedirection of the light distribution angle of 0 degrees, and prevents theluminous intensity at the light distribution angle of 0 degree fromincreasing too much.

On the other hand, as indicated by the light ray B in FIG. 2, lightwhich travels toward the outer circumferential surface 19 through theperiphery of the hollow part 21 from the end point A6 of the lightemitting surface 14 approaches the outer circumferential surface 19, atan incident angle of θC or more in relation to the outer circumferentialsurface 19. Light which is made to approach the outer circumferentialsurface 19 is totally reflected toward the first light diffusing surface26 of the hollow part 21.

In the present embodiment, the diffusion region 27 is configured by atapered surface inclined so as to gradually approach the optical axis O1from the first light diffusing surface 26 toward the bottom surface 25.Therefore, the bottom surface 25 which faces the incident plane 18 isnarrow, and can reduce the ratio at which the light made to enter thelight guide column 16 from the incident plane 18 is reflected on thebottom surface 25 and tries to return in a direction toward the incidentplane 18.

In other words, most of the light which is made to enter from theincident plane 18 is not reflected on the bottom surface 25 but is ledto the outer circumferential surface 19 as a total reflection surfacethrough the periphery of the hollow part 21. Therefore, the light whichis made to enter into the incident plane 18 can be efficiently led tothe outer circumferential surface 19 and be totally reflected.

The light intensity at the light distribution angle of 0 degrees hasbeen found to tend to decrease if the diffusion region 27 of the hollowpart 21 is sharpened to be tapered. In addition, if the diffusion region27 of the hollow part 21 is sharpened, the diffusion region 27 isdifficult to process, which makes it difficult to improve processingaccuracy of the hollow part 21.

Light which is totally reflected on the outer circumferential surface 19of the light guide column 16 toward the first light diffusing surface 26penetrates and is diffused by the first light diffusing surface 26.Here, diffusion of light is supposed to be of a semi-Lambertian(approximate Lambertian) type.

Then, the light which is reflected and diffused by the first lightdiffusing surface 26 is diffused in the semi-Lambertian manner,centering on an inward normal toward the outer circumferential surface19 from a point on the first light diffusing surface 26, and is emittedfrom the outer circumferential surface 19 toward the globe 3.

The light which penetrates and is diffused by the first light diffusingsurface 26 reaches the inner surface 23 of the hollow part 21 andpenetrates and is diffused, or is reflected and diffused. Further, sincean air layer 33 exists between the first light diffusing surface 26 ofthe hollow part 21 and the second light diffusing surface 30 of thelight diffuser 17, the light reaches and is diffused not only by thefirst light diffusing surface 26 but also by the second light diffusingsurface 30. Owing to this recursive diffusion, final diffusion of lightis of a perfect Lambertian type. Therefore, light can be advantageouslydiffused over a wide range for achieving a wide light distribution.

The light which is reflected and diffused by the inner surface 23 of thehollow part 21 is further Lambertian-type diffused, centering on aninward normal toward the outer circumferential surface 19 from a pointon the first light diffusing surface 26, and is finally emitted from theouter circumferential surface 19 toward the globe 3.

As a result, strongly directive light emitted from the light emittingsurface 14 of the light emitting module 4 is diffused in all directionswhen the light is radiated from the outer circumferential surface 19 ofthe tip end of the light guide column 16. Accordingly, a wide lightdistribution is achieved.

If the normal vector of the inner surface 23 of the hollow part 21 weresupposed to correspond to the direction of the optical axis O1, thelight which reaches the inner surface 23 of the hollow part 21 werediffused in the semi-Lambertian manner with reference to the opticalaxis O1. Most of the light components which reached and were reflectedby the inner surface 23 of the hollow part 21 return in the directiontoward the light-emitting module 4 through the light guide column 16.Therefore, the luminaire efficiency of the LED lamp 1 would havedeteriorated.

On the other hand, the component of light which penetrated the innersurface 23 of the hollow part 21 would have the maximum lightdistribution angle of 60 degrees or so at which ½ of the luminousintensity at the light distribution angle of 0 degrees is obtained, evenif diffusion of light is of the Lambertian type.

In contrast, when the normal vector of the inner surface 23 of thehollow part 21 is perpendicular to the optical axis O1 as is the case ofthis embodiment, the light which reaches the inner surface 23 of thehollow part 21 is semi-Lambertian diffused with reference to the vectorperpendicular to the optical axis O1.

As a result, the light which is reflected by the inner surface 23 andreturns in the direction to the light emitting module 4 decreases incomparison with the case where the normal vector of the inner surface 23of the hollow part 21 corresponds to the direction of the optical axisO1. Therefore, the luminaire efficiency of the LED lamp 1 can beprevented from deterioration.

Further, the component of the light which penetrates the inner surfaceof the hollow part 21 has a distribution angle which can be as wide as150 degrees at maximum. In addition, when light is finally emitted fromthe light guide column 16, the light distribution angle widens much moreowing to refraction of light by the outer circumferential surface 19.

That is, the light distribution angle can be large even though thedirectivity of the light emitted from the light emitting surface 14 ofthe light emitting module 4 is strong. In actual practice, some of lightof the light emitting diodes 14 emitted through the light emittingsurface 14 is finally radiated from the light guide column 16 indirections within the light distribution angle of 90 degrees. Therefore,the light distribution angle of the light finally emitted from the lightguide column 16 is within a range of 0 to 150 degrees. Therefore, themaximum value of the light distribution angle at which half of themaximum luminous intensity is obtained can be approximately 300 degrees.

From the above, when the normal vector of the inner surface 23 of thehollow part 21 is perpendicular to the optical axis O1, a wide lightdistribution with which the ½ light distributing angle is approximately300 degrees can be achieved while preventing the luminaire efficiency ofthe LED lamp 1 from deterioration.

In other words, of the light which is made to enter the light guidecolumn 16 from the incident plane 18, the component of light which isgoing to return in the direction to the incident plane 18 can be reducedby providing the first light diffusing surface 26 parallel to theoptical axis O1 in the inner surface 23 of the hollow part 21. At thesame time, the component of light which is emitted in all directionsfrom the outer circumferential surface 19 of the light guide column 16can be increased. Therefore, the light emitted from the light emittingmodule 4 can be efficiently used for the purpose of lighting.

The length L along the axial direction of the optical axis O1 of thefirst light diffusing surface 26 of the hollow part 21 is important inefficiently guiding the light totally reflected on the outercircumferential surface 19 of the light guide column 16 to outside ofthe light guide column 16. Next, the length L of the first lightdiffusing surface 26 will be described with reference to a light guidecolumn 36 which has a simpler shape than the actual light guide column16.

FIG. 4 shows a cylindrical light guide column 36 whose length, outerdiameter, and inner diameter are L′, 2R₁′, and 2R₂′, respectively. Thecylindrical light guide column 36 is rotationally symmetrical about theaxis line O2. The outer radius R₂′ of the cylindrical light guide column36 is 2.0 mm, and the inner radius R₁′ thereof is 1.0 mm. Further, thecylindrical light guide column 36 is made of transparent acryl, and hasa refractive index n of 1.49.

As shown in FIG. 4, the cylindrical light guide column 36 comprises anannular incident end surface 37, an annular tip end surface 38, an innercircumferential surface 39, and an outer circumferential surface 40. Theincident end surface 37 is positioned at an end along the axialdirection of the cylindrical light guide column 36, and faces an annularlight source (not shown). The light distribution of the light source isof the Lambertian type, and all the light emitted from the light sourceenters the incident end face 37.

The tip end surface 38 is positioned in the other end along the axialdirection of the cylindrical light guide column 36, and perfectlyabsorbs the light which is made to enter the cylindrical light guidecolumn 36 from the incident end surface 37. The inner circumferentialsurface 39 reflects all the light which reaches the innercircumferential surface 39 by reflection of the Lambertian type.

Under conditions described above, all light fluxes emitted from theouter circumferential surface 40 of the cylindrical light guide column36 can be calculated by using a ray tracing simulation. Light Tools(registered trademark) manufactured by Synopsys was used in thissimulation.

FIG. 5 shows a calculation result when the length L′ of the cylindricallight guide column 36 was changed variously. In FIG. 5, the axis ofabscissa represents the length L′ of the cylindrical light guide column36 which is standardized by an expression below (obtained by dividing L′by L_(F)).L _(F)=2(R ₂ −R ₁)tan θ_(C)  (7)The standardized length L′ is expressed as L*. Here, L_(F) correspondsto the right side of the foregoing expression (2).

In FIG. 5, the main axis of the ordinate on the left side represents aratio of all light fluxes of light emitted from the outercircumferential surface 40 of the cylindrical light guide column 36 inrelation to all fluxes of light emitted from the annular light source.This ratio is expressed as ε. Further in FIG. 5, the sub-axis ofordinate on the right side represents a differential coefficient of ε inrelation to L*.

According to FIG. 5, ε increases in accordance with increase of L*, andis uniquely stabilized when L* reaches approximately 16. Hence, asetting of L*=16 can be said to increase all fluxes of light emittedfrom the outer circumferential surface 40 of the cylindrical light guidecolumn 36. However, in consideration of the compactness of thecylindrical light guide column 36, a smaller L* is better.

Also, according to FIG. 5, the differential coefficient is maximizedwhen L* is approximately 1. This means that, when L* is close to 1, alllight fluxes of the light emitted from the outer circumferential surface40 are abruptly increased by extending L*. That is, all the light fluxescan be efficiently increased by setting L* to be 1 or more.

This feature can be proved also from FIG. 6. FIG. 6 shows a partialcross section of the cylindrical light guide column 36 which extendsthrough the center axis O2. Supposing that light is diffused andreflected at an arbitrary point P1 on the inner circumferential surface39 of the cylindrical light guide column 36, diffused light D as shownin FIG. 6 appears.

Here, the critical angle θ_(C) is supposed to be a total reflectionangle at which a light ray E of the diffused light D is totallyreflected on the outer circumferential surface 40 of the cylindricallight guide column 36. At this time, in order to diffuse again the lightray E on the inner circumferential surface 39, which has been totallyreflected once on the outer circumferential surface 40, the length L′ ofthe inner circumferential surface 39 along the axial direction of theaxis line O2 needs to be L* or more.

Conversely, if the length L′ is L* or more, a light ray F, which travelsthrough an arbitrary point P2 at a position more shifted away in adirection toward the outer circumferential surface 40 than the point P1and has a critical angle θ_(C) as the total reflection angle on theouter circumferential surface 40, is led to and diffused on the innercircumferential surface 39.

In other words, if the length L′ of the inner circumferential surface 39is L* or more, there is light which travels through the point P1 and isrecursively diffused on the inner circumferential surface 39. Otherwise,if the length L′ is smaller than L*, there is no light which travelsthrough the point P1 and is recursively diffused on the innercircumferential surface 39.

Therefore, when the length L′ of the inner circumferential surface 39 isL* or more, the light which is recursively diffused on the innercircumferential surface 39 reaches the outer circumferential surface 40,and the quantity of light emitted from the outer circumferential surface40 increases. From the above, L* may be set to be not smaller than 1 andnot greater than 16.

Accordingly, the length L of the first light diffusing surface 26 of thehollow part 21 desirably satisfies a relationship below.

$\begin{matrix}{1 \leq \frac{L}{2\left( {R_{2} - R_{1}} \right)\tan\;\theta_{C}} \leq 16} & (8)\end{matrix}$

Further in FIG. 2, a light ray B which travels through the periphery ofthe hollow part 21 from an end point A6 of the light emitting surface 14toward the outer circumferential surface 19 is supposed to be totallyreflected at the critical angle θ_(C) on the outer circumferentialsurface 19. At this time, the light which is totally reflected on theouter circumferential surface 19 is supposed to be made to reach thefirst light diffusing surface 26 of the hollow part 21 at a point Q.

Then, all the light which is totally reflected on the outercircumferential surface 19 immediately after being emitted from thelight emitting surface 14 is made to reach the first light diffusingsurface 26 at a position apart from the point Q in the direction towardthe tip end surface 20 of the light guide column 16, or is made todirectly enter the tip end surface 20.

At this time, a distance H₀ to the light emitting surface 14 along theaxial direction of the optical axis O1 from the point Q where the lightray B is made to enter the first light diffusing surface 26 can beexpressed as follows.H ₀=(2R ₂ +R ₃ −R ₁)tan θ_(C)  (9)

Therefore, a relationship below needs to be satisfied in order to leadlight, which is totally reflected on the outer circumferential surface19 immediately after emitting from the light emitting surface 14, to thefirst light diffusing surface 26.H≧H ₀  (10)This relationship is equivalent to the foregoing expression (4).

In the LED lamp 1 according to the first embodiment, most of the strongdirective light of the light emitting diodes 11 is led to the hollowpart 21 positioned at the tip end of the light guide column 16 afterbeing made to enter the incident plane 18 of the light guide column 16,and is diffused in all directions from the tip end of the light guidecolumn 16.

That is, the tip end of the light guide column 16 positioned in thecentral part of the globe 3 is the center of light from which the lightis emitted over a wide range. Additionally, owing to the transparentappearance of the tip end of the light guide column 16 which emits lightthrough the transparent globe 3, light can be obtained which creates asense of glittering like a clear chandelier bulb.

Further, the first light diffusing surface 26 to which light totallyreflected on the outer circumferential surface 19 of the light guidecolumn 16 is led is arranged along the optical axis O1. Accordingly, thecomponent of light which is diffused on the first light diffusingsurface 26 and is going to return to the light emitting module 4 isreduced, and the length L of the first light diffusing surface 26 isdefined. Therefore, a light distribution angle of 300 degrees equivalentto an incandescent light bulb can be achieved efficiently.

Accordingly, there is provided an LED lamp 1 which has high luminaireefficiency and has a point light source with wide light distribution.

The configuration of the light emitting module is not particularlylimited to the first embodiment described above. For example, two ormore types of light emitting diodes which emit different colors may becombined.

According to such a configuration as described, light of a plurality ofcolors emitted from the light emitting diodes mixes sufficiently throughthe process of diffusion inside the light guide column. As a result, thecolor of light finally emitted from the tip end of the light guidecolumn hardly varies and illumination light with little colorirregularity can be obtained.

Further, the light emitting module is not limited to the COB type butmay employ, for example, a plurality of SMD-type (surface mount devicetype) light emitting modules.

Second Embodiment

FIGS. 7, 8, 9, 10, 11, and 12 disclose the second embodiment.

An LED lamp 51 according to the second embodiment is different from thefirst embodiment described above in the configuration of a lamp body 52,a globe 53, and a light guide 54.

As shown in FIG. 7, the lamp body 52 comprises a support part 56 whichcloses an open end part of a base 7. A light emitting module 4 which isa light source of the LED lamp 51 is fixed to a central part of thesupport part 56 by screwing or adhesion. A lighting circuit 5 whichsupplies a constant current to the light emitting module 4 is containedin the base 7.

The globe 53 has a shape similar to a glass bulb of a clear electriclight bulb and is made of a transparent synthetic resin material such asacryl or transparent glass. An open end of the globe 53 is jointedcoaxially with the support part 56 of the lamp body 52. The globe 53 isarranged coaxially with the optical axis O1 of the light emitting module4.

Therefore, the LED lamp 51 according to the present embodiment has ashape which is extremely similar to a clear electric light bulb.

As shown in FIGS. 7 and 8, a light guide 54 is contained in the globe 53so as to face a light emitting surface 14 of the light emitting module4. The light guide 54 comprises a light guide column 58 and a lightdiffuser 59.

The light guide column 58 is an example of a light guide member and isprovided coaxially with the optical axis O1. The light guide column 58has an approximately circular conical shape which is rotationallysymmetrical about the optical axis O1 which has a maximum diameter of,for example, 4.2 mm. Further, the light guide column 58 is made of, forexample, transparent acryl. Acryl has a refractive index n of 1.49.

As shown in FIG. 8, the light guide column 58 comprises an incidentplane 60, an outer circumferential 61, and a hollow part 62. Theincident plane 60 is a flat circular surface perpendicular to theoptical axis O1, and faces the light emitting surface 14 of the lightemitting module 4. The incident plane 60 has substantially the same sizeas the light emitting surface 14.

An outer circumferential surface 61 extends in a direction extendingaway from the light emitting module 4 so as to coaxially surround theoptical axis O1 from an outer peripheral edge of the incident plane 60.The outer circumferential surface 61 extends in parallel with theoptical axis O1. The outer circumferential surface 61 can also bereferred to as a total reflection surface which totally reflects lightof the light emitting module 11 which is made to enter the light guidecolumn 58 from the incident plane 60. The outer circumferential surface61 as a total reflection surface is finished into a smooth glossysurface.

According to the present embodiment, a tapered region 64 is provided ata tip end of the light guide column 58. The tapered region 64 isinclined to be slightly curved toward the optical axis O1 with increaseddistance from the incident plane 60 in an axial direction of the opticalaxis O1. Therefore, the outer circumferential surface 61 of the lightguide column 58 is inclined to approach the optical axis O1 at positionscorresponding to the tapered region 64.

As shown in FIGS. 8 and 9, the hollow part 62 is provided at the tip endof the light guide column 58 which is apart from the incident plane 60.The hollow part 62 has an approximately cylindrical shape coaxial withthe optical axis O1 and is open in the tip end of the light guide column58.

An inner surface 65 which defines the hollow part 62 comprises acircumferential surface 66 surrounding the optical axis O1 and a bottomsurface 67 perpendicular to the optical axis O1. The circumferentialsurface 66 includes the first light diffusing surface 68 parallel to theoptical axis O1. The first light diffusing surface 68 is included in thetapered region of the light guide column 58. The bottom surface 67 facesthe incident plane 60 at the bottom of the hollow part 62.

Further, the inner surface 65 of the hollow part 62 comprises adiffusion region 69 which connects the first light diffusing surface 68and the bottom surfaces 67. The diffusion region 69 is defined by atapered surface inclined so as to gradually approach the optical axis O1from the first light diffusing surface 68 toward the bottom surface 67.The inner surface 65 of the hollow part 62 including the first lightdiffusing surface 68 is made of a rough surface having lightdiffusibility. The rough surface is formed by so-called sandblasting ofspraying, for example, a polishing material having a grain diameter of100 μm to the inner surface 65.

FIG. 9 shows a cross sectional shape of the hollow part 62 where thelight guide column 58 is cut along a plane including the optical axisO1. According to the present embodiment, a distance R₁ to the opticalaxis O1 along a direction perpendicular to the optical axis O1 from thefirst light diffusing surface 68 is supposed to be 1.3 mm, a maximumdistance R₂ to the optical axis O1 along a direction perpendicular tothe optical axis O1 from the outer circumferential surface 61 of thelight guide column 58 including the first light diffusing surface 68 issupposed to be 2.0 mm, and a length L of the first light diffusingsurface 66 along the axial direction of the optical axis O1 is supposedto be 3.4 mm.

Then, the first light diffusing surface 68 of the hollow part 62satisfies a relationship below where a critical angle is expressed asθ_(C).L=3.4≧2(R ₂ −R ₁)tan θ_(C)=1.3  (11)

Further in the present embodiment, a maximum distance H from anarbitrary point on the first light diffusing surface 68 to the lightemitting surface 14 is set to H=22.3 mm.

As shown in FIGS. 8, 9, and 10, the light diffuser 59 of the light guide54 is contained in the hollow part 62 of the light guide column 58. Thelight diffuser 59 is made of, for example, transparent acryl.

The light diffuser 59 comprises a post part 71 and a cylinder part 72.The post part 71 is a solid cylindrical component having a smallerdiameter than the hollow part 62, and has a second light diffusingsurface parallel to the optical axis O1. Further, a flange part 74 iscoaxially formed at an end of the post part 71. The flange part 74protrudes in radial directions of the post part 71 from the outercircumferential surface 73.

The cylinder part 72 comprises an inner circumferential surface 75 andan outer circumferential surface 76 both parallel to the optical axisO1. The cylinder part 72 is fixed to a lower surface of the flange part74 by means of adhesion so as to coaxially surround the post part 71,and is thereby integrated with the post part 71.

The flange part 74 is fixed to a tip end of the light guide column 58 bymeans of adhesion so as to close an open end of the hollow part 62. Bythis fixture, the post part 71 and the cylinder part 72 of the lightdiffuser 59 are coaxially held inside the hollow part 62.

Further, a first air layer 78 is provided between the first lightdiffusing surface 68 of the hollow part 62 and the outer circumferentialsurface 76 of the cylinder part 72, and a second air layer 79 isprovided between the inner circumferential surface 75 of the cylinderpart 72 and the outer circumferential surface 73 of the post part 71.

According to the present embodiment, the outer circumferential surface73 of the post part 71, and the inner circumferential surface 75 andouter circumferential surface 76 of the cylinder part 72 are made ofrough surfaces having light diffusibility. The rough surfaces are formedby so-called sandblasting of spraying, for example, a polishing materialhaving a grain diameter of 100 μm to the post part 71.

Therefore, the outer circumferential surface 73 of the post part 71, andthe inner circumferential surface 75 and outer circumferential surface76 of the cylinder part 72 can function as a second light diffusingsurface, a third light diffusing surface, and a fourth light diffusingsurfaces, respectively.

In the light guide column 58 having such a light diffuser 59 asdescribed, an end which comprises the incident plane 60 is held in thesupport part 56 of a lamp body 2. Therefore, the tapered region 64 ofthe light guide column 58 including the light diffuser 59 is positionedin the central part of the globe 53.

Strongly directive light which is emitted from the light emittingsurface 4 of the light emitting module 4 is made to enter the lightguide column 58 through the incident plane 60. The light which is madeto enter the light guide column 58 is totally reflected on the outercircumferential surface 61, and travels toward the hollow part 62. Lightwhich travels through the vicinity of the hollow part 62 toward thetapered region 64 enters the tapered region 64 at an incident angle tothe tapered region 64 of not less than critical angle θ_(C), inaccordance with the inclination of the tapered region 64. Thus the lightwhich is made to enter the tapered region 64 is totally reflected towardthe first light diffusing surface 68 of the hollow part 62.

FIG. 11 is a diagram showing light rays obtained by simulating lightrays which travel toward the tapered region 64 through a point Gpositioned near a boundary between the first light diffusing surface 68and the diffusion region 69. FIG. 11 shows a partial cross section ofthe tapered region 64 of the light guide column 58 including the opticalaxis O1.

According to FIG. 11, the light which travels through the point G towardthe tapered region 64 is totally reflected on the tapered region 64toward the first light diffusing surface 68 of the hollow part 62, andis diffused on the first light diffusing surface 68.

At this time, as the length L of the first light diffusing surface 68satisfies the foregoing expression (2), the light which is totallyreflected on the tapered region 64 after passing the point G isinevitably led to the first light diffusing surface 68.

Further according to the present embodiment, the first air layer 78 isprovided between the first light diffusing surface 68 of the hollow part62 and the outer circumferential surface 76 of the cylinder part 72, andthe second air layer 79 is provided between the inner circumferentialsurface 75 of the cylinder part 72 and the outer circumferential surface73 of the post part 71. Therefore, the light diffused on the first lightdiffusing surface 68 penetrates the cylinder part 71 through the firstair layer 78, and penetrates the post part 71 through the second airlayer 79.

That is, when the light which travels in a direction intersecting theoptical axis O1 from the first light diffusing surface 68 passes theouter circumferential surface 76 of the inner circumferential surface 75of the cylinder part 72 and the outer circumferential surface 73 of thepost part 71, the light is diffused a number of times corresponding tothe number of surfaces described above. As a result, light can bediffused over a wider range and the light distribution angle of thelight finally emitted from the tapered region 64 of the light guidecolumn 58 can be widened.

FIG. 12 shows a result of performing a ray-tracing simulation of lightdistribution of light emitted from the light guide column 58 which isprovided with the light diffuser 59 in the LED lamp 51 according to thepresent embodiment. In FIG. 12, luminous intensity is expressed as aradar chart in relation to a light ray direction in which the directionof light extracted along the optical axis O1 of the light emittingmodule 4 is set to 0 degrees.

According to FIG. 12, the intensity of light emitted in the directionperpendicular to the optical axis O1 is great, and the maximum luminousintensity falls within a range of 90 to 120 degrees relative to theoptical axis O1. On a light distribution curve shown in FIG. 12, a lightdistribution angle defined by two directions, at which half of theluminous intensity of the maximum luminous intensity is obtained, isapproximately 320 degrees, which is substantially equivalent to anincandescent light bulb.

Further, it has been confirmed that the luminaire efficiency of the LEDlamp 51 is 90% where an absorption factor of light which reenters thelight-emitting module 4 is 60%.

According to the second embodiment, the tapered region 64 inclined in adirection towards the optical axis O1 is provided at the tip end of thelight guide column 58, and the first light diffusing surface 68 parallelto the optical axis O1 is included in the tapered region 64.

In this manner, a normal vector which extends toward the optical axis O1from an arbitrary point on the tapered region 64 is inclined so as to bedirected to the bottom of the hollow part 62 in relation to a linesegment perpendicular to the optical axis O1. Therefore, in comparisonwith the outer circumferential surface of the light guide column 58which is parallel to the axial direction of the optical axis O1, thelength L of the first light diffusing surface 68 can be shortened.

As a result, the light guide column 58 can have a compact shape, and theshape of light emitted from the tip end of the light guide column 58 ismuch closer to that of a point light source. Therefore, in cooperationwith the transparent appearance of the tip end of the light guide column58 which emits light through the transparent globe 3, light can bespread to create a sense of glittering highly similar to that of a clearelectric light bulb.

Third Embodiment

FIGS. 13, 14, and 15 disclose the third embodiment.

An LED lamp 100 according to the third embodiment is different from thesecond embodiment principally in a light guide 101 and a configurationof supporting the light guide 101 by a lamp body 52. The remainingconfiguration is basically the same as that of the second embodiment.Therefore, in the third embodiment, the same components as those in thesecond embodiment will be denoted with the same reference signs,respectively, and descriptions thereof will be omitted.

As shown in FIG. 13, a stay 102 is supported at a central part of a lampbody 52. The stay 102 is made of a metal material having more excellentthermal conductivity than iron, such as aluminum, and functions also asa heat radiator. The stay 102 is covered with a globe 53, and isprotruded toward the central part of the globe 53 from the lamp body 52.

A light emitting module 4 which is a light source of the LED 100 isfixed to a central part of the stay 102 by, for example, screwing oradhesion. The stay 102 is arranged to be coaxial with an optical axis O1of the light emitting module 4. A lighting circuit 5 which supplies aconstant current to the light emitting module 4 is contained in a base7.

In the present embodiment, a light emitting surface 14 of the lightemitting module 4 is, for example, a square whose edges each have alength of 3.2 mm. As shown in FIG. 15, a distance R₃ to the optical axisO1 along the direction perpendicular to the optical axis O1 from an endpoint A6 on a peripheral edge of the light emitting surface 14 can beexpressed as follows where C is the area of the light emitting surface14.

$\begin{matrix}{R_{3} = \sqrt{\frac{C}{\pi}}} & (12)\end{matrix}$Accordingly, the distance R3=1.8 is obtained.

As shown in FIGS. 13 and 14, the light guide 101 is contained inside theglobe 53 so as to face the light emitting surface 14 of the lightemitting module 4. The light guide 101 comprises a light guide column103 and a light diffuser 104.

The light guide column 103 is an example of a light guide member and isprovided coaxially with the optical axis O1. The light guide column 103has a shape which is rotationally symmetrical about the optical axis O1.Further, the light guide column 103 is made of, for example, transparentacryl, though is not limited to acryl. Any material can be appropriatelyselected and used insofar as the material allows visible light topenetrate.

The light guide column 103 comprises a first end 103 a and a second end103 b which are apart from each other in an axial direction of theoptical axis O1. The first end 103 a of the light guide column 103 has ashape one size greater than the light emitting surface 14, and anincident plane 106 is formed in the first end 103 a. The incident plane106 has a semi-spherical shape which is recessed toward the inside ofthe light guide column 103, centering on the optical axis O1. Theincident plane 106 has a radius of 2.0 mm.

Further, the light guide column 103 comprises an outer circumferentialsurface 107 which connects the first end 103 a and the second end 103 b.The outer circumferential surface 107 coaxially surrounds the opticalaxis O1, and is arcuately curved so as to extend in a directionperpendicular to the optical axis O1 in an intermediate part 103 cbetween the first end 103 a and the second end 103 b of the light guidecolumn 103.

In other words, the outer circumferential surface 107 of the light guidecolumn 103 comprises a first tapered region 108 positioned between thefirst end 103 a and the intermediate part 103 c of the light guidecolumn 103, and a second tapered region 109 positioned between thesecond end 103 b and the intermediate part 103 c of the light guidecolumn 103.

The first tapered region 108 is curved so as to approach the opticalaxis O1, from the intermediate part 103 c along a direction toward thefirst end 103 a. The second tapered region 109 is curved so as toapproach the optical axis O1, from the intermediate part 103 c along adirection toward the second end 103 b.

Therefore, the intermediate part 103 c of the light guide column 103defines the maximum diameter of the light guide column 103. In thepresent embodiment, the light guide column 103 has the maximum diameterof 9.0 mm. The incident plane 106 of the light guide column 103 isinside the first tapered region 108.

The outer circumferential surface 107 including the first tapered region108 and the second tapered region 104 can function as a total reflectionsurface which totally reflects light of the light emitting module 11which is made to enter the light guide column 103 from the incidentplane 106. The outer circumferential surface 107 as a total reflectionsurface is finished into a smooth glossy surface.

As shown in FIG. 14, a hollow part 111 is provided in the light guidecolumn 103 in the side of the second end 103 b. The hollow part 111 hasan approximately cylindrical shape coaxial with the optical axis O1 andis open in the side opposite to the light guide column 106.

An inner surface 112 which defines the hollow part 111 comprises acircumferential surface 113 surrounding the optical axis O1 and a bottomsurface 114 perpendicular to the optical axis O1. The circumferentialsurface 113 includes a first light diffusing surface 115 parallel to theoptical axis O1. The first light diffusing surface 115 is inside thesecond tapered region 109 of the light guide column 103. The bottomsurface 114 faces the incident plane 106 at the bottom of the hollowpart 111.

Further, the inner surface 112 of the hollow part 111 comprises adiffusion region 116 which connects the first light diffusing surface115 and the bottom surfaces 114. The diffusion region 116 is defined bya tapered surface inclined so as to gradually approach the optical axisO1 from the first light diffusing surface 115 toward the bottom surface114.

The inner surface 112 of the hollow part 111 including the first lightdiffusing surface 115 is made of a rough surface having lightdiffusibility. The rough surface is formed by so-called sandblasting ofspraying, for example, a polishing material having a diameter of 100 μmto the inner surface 112.

FIG. 14 shows a cross-sectional shape of the hollow part 111 where thelight guide column 103 is cut along a plane including the optical axisO1. According to the present embodiment, a distance R₁ to the opticalaxis O1 along the direction perpendicular to the optical axis O1 fromthe first light diffusing surface 115 is supposed to be 1.4 mm, amaximum distance R₂ to the optical axis O1 along the directionperpendicular to the optical axis O1 from the second tapered region 109which includes the first light diffusing surface 115 is supposed to be4.0 mm, and a length L of the first light diffusing surface 115 alongthe axial direction of the optical axis O1 is supposed to be 7.0 mm.

Then, the first light diffusing surface 115 of the hollow part 111satisfies a relationship below where a critical angle is expressed asθ_(C).L=7.0≧2(R ₂ −R ₁)tan θ_(C)=4.7  (13)

Further, in the present embodiment, a maximum distance H from anarbitrary point on the first light diffusing surface 115 to the lightemitting surface 14 is set to H=15.0 mm.

A specific shape of the outer circumferential surface 107 of the lightguide column 103 will be described with reference to FIG. 14. In FIG.14, shown is a line segment which extends from an arbitrary point on theincident plane 106 of the light guide column 103 as a start point and isperpendicular to the optical axis O1. Among points at which the linesegment intersects the optical axis O1, a point closest to the lightemitting surface 14 is expressed as O′.

The point O′ is taken as an origin point. A direction of light extractedalong the optical axis O1 from the point O′ is expressed as a directionz. A direction which is perpendicular to the optical axis O1 and extendsalong the light emitting surface 14 is expressed as a direction x.Further, a distance to the first end 103 a from a point on the x-axis,which is closest to an end point A6 on a peripheral edge of the lightemitting surface 14, is expressed as l. The shape of the outercircumferential surface 107 as a total reflection surface can beexpressed as follows.x=lexp(tan θ_(a)Θ)cos Θ−R ₃  (14)z=lexp(tan θ_(a)Θ)sin Θ  (15)

In the foregoing expressions (14) and (15), the parameter Θ represents afinite range included in a range expressed below.

$\begin{matrix}{0 \leq \Theta \leq \frac{\pi}{2}} & (16)\end{matrix}$

In the foregoing expressions (14) and (15), the real constant θ_(a)represents a finite range included in a range expressed below.

$\begin{matrix}{\theta_{C} \leq \theta_{a} < \frac{\pi}{2}} & (17)\end{matrix}$

In the foregoing expressions (14) and (15), the real constant l is asfollows.l≧2R ₃  (18)

Thus, by defining the shape of the outer circumferential surface 107 ofthe light guide column 103, most of the light which is made to enter thelight guide column 103 from the incident plane 106 can be totallyreflected on the outer circumferential surface 107.

At this time, the distance to the optical axis O1 along the directionperpendicular to the optical axis O1 from the outer circumferentialsurface 107 at the point on the outer circumferential surface 107 atwhich Θ=θ_(a) is given is maximized. An inward normal which extendstoward the optical axis O1 from the point at which Θ=θ_(a) is given isperpendicular to the optical axis O1.

In the present embodiment, the shape of the outer circumferentialsurface 107 of the light guide column 103 is greatly different from astraight circular column. Therefore, the expression (4) of the firstembodiment described above is not applicable.

As shown in FIG. 14, the light diffuser 104 of the light guide 101 isalmost completely contained in the hollow part 111 of the light guidecolumn 103. The light diffuser 104 is made of, for example, transparentacryl, though is not limited to acryl. Any material can be appropriatelyselected and used insofar as the material allows visible light topenetrate.

The light diffuser 104 comprises a post part 118 and a flange part 119.The post part 118 is a solid cylindrical component having a smallerdiameter than the hollow part 111, and has a second light diffusingsurface 120 parallel to the optical axis O1, and a flat end surface 121perpendicular to the optical axis O1.

The flange part 119 is formed coaxially on the end opposite to the endsurface 121 of the post part 118, and protrudes in radial directions ofthe post part 118.

The flange part 119 is fixed to a second tip end 103 of the light guidecolumn 103 by means of adhesion so as to close an open end of the hollowpart 111. By this fixture, the post part 118 of the light diffuser 104is held coaxially inside the hollow part 111, and an air layer 122 isprovided between the first light diffusing surface 115 of the hollowpart 111 and the second light diffusing surface 120 of the lightdiffuser 104.

According to the present embodiment, surfaces of the second lightdiffusing surface 120 of the light diffuser 104, the end surface 121,and the flange part 119 are made of rough surfaces having lightdiffusibility. The rough surfaces are formed by so-called sandblastingof spraying, for example, a polishing material having a grain diameterof 100 μm to the light diffuser 17.

Further, the light guide column 103 comprising the light diffuser 104 ispositioned in the central part of the globe 53.

Strongly directive light which is emitted from the light emittingsurface 14 of the light emitting module 4 is made to enter the lightguide column 103 through the incident plane 106. The incident plane 106,which is semi-spherically recessed, guides light to the first taperedregion 108 of the outer circumferential surface 107, withoutsubstantially changing refraction directions of the light, when lightemitted from the peripheral part of the light emitting surface 14 ismade to enter.

FIG. 15 is a diagram showing light rays obtained by simulating lightrays R which travel from the peripheral part of the light emittingsurface 14 toward the incident plane 106. FIG. 15 shows a partial crosssection of the first tapered region 108 of the light guide column 103including the optical axis O1.

According to FIG. 15, the light which travels toward the incident plane106 from the peripheral part of the light emitting surface 14 penetratesinside of the light guide column 103 and further travels toward thefirst tapered region 108, without substantially changing incidentdirections relative to the incident plane 106.

That is, if light which is made to enter the incident plane 106 isrefracted greatly, the component of light which returns from theincident plane 106 to the light emitting surface 14 increases, and thelight is absorbed by the light emitting module 4. In contrast, in thepresent embodiment, light which is made to enter the incident plane 106is led to the first tapered region 108, without substantially changingincident directions, and is totally reflected thereon.

Therefore, loss of light which is made to enter the light guide column103 can be suppressed as much as possible, and the luminaire efficiencyof the LED lamp 100 improves.

The light which is totally reflected on the first tapered region 108penetrates inside of the light guide column 103 toward the hollow part111, and reaches and is diffused on the inner surface 112 of the hollowpart 111 and the light diffuser 104. The diffused light is diffused inall directions principally from the second tapered region 109 of thelight guide column 103.

According to the third embodiment, the second tapered region 109inclined in a direction towards the optical axis O1 is provided at thetip end of the light guide column 103, and the first light diffusingsurface 115 parallel to the optical axis O1 is included in the secondtapered region 109.

In this manner, a normal vector which extends toward the optical axis O1from an arbitrary point on the second tapered region 109 is inclined soas to be directed to the bottom of the hollow part 111 in relation to aline segment perpendicular to the optical axis O1. Therefore, incomparison with the outer circumferential surface of the light guidecolumn 103 which is parallel to the axial direction of the optical axisO1, the length L of the first light diffusing surface 115 can beshortened.

As a result, the light guide column 103 can have a compact shape, andthe shape of light emitted from the tip end of the light guide column103 is much closer to that of a point light source. Therefore, incooperation with the transparent appearance of the tip end of the lightguide column 103 which emits light through the transparent globe 53,light can be spread to create a sense of glittering highly similar to aclear electric light bulb.

In the first through third embodiments, the light diffuser contained inthe hollow part of the light guide column is not a mandatory componentbut may be omitted depending on targeted light distributioncharacteristics. If the light diffuser is omitted, for example, acoating material including particles which highly scatter light isdesirably coated on the inner surface of the hollow part, to improve thelight-diffusing performance of the inner surface.

While certain embodiments have been described, these embodiments havebeen presented by way of example only, and are not intended to limit thescope of the inventions. Indeed, the novel embodiments described hereinmay be embodied in a variety of other forms; furthermore, variousomissions, substitutions and changes in the form of the methodsdescribed herein may be made without departing from the spirit of theinventions. The accompanying claims and their equivalents are intendedto cover such forms or modifications as would fall within the scope andspirit of the inventions.

Additionally, configurations of a light guide according to the presentinvention will be described hereinafter.

[1] A light guide which is provided coaxially with an axis extendingthrough a centroid of the light emitting surface along a directionperpendicular to the light emitting surface, and allows light emittedfrom the light emitting surface to penetrate, comprising:

an incident plane facing the light emitting surface;

a total reflection surface which is extended from an outer peripheraledge of the incident plane in a direction extending away from the lightemitting surface so as to surround the axis, and is configured tototally reflect the light which is made to enter the light guide fromthe incident plane;

a hollow part which is provided at a position distant from the incidentplane along an axial direction of the axis, and comprises a first lightdiffusing surface parallel to the axis, to which the light totallyreflected on the outer circumferential surface is led; and

a light diffuser provided in the above-mentioned hollow part.

[2] The light guide described in the foregoing article [1], wherein thelight diffuser comprises a second light diffusing surface facing thefirst light diffusing surface, and an air layer is provided between thefirst light diffusing surface and the second light diffusing surface.

[3] The light guide described in the foregoing article [1], wherein thelight diffuser comprises a solid post part and a cylinder part whichsurrounds the post part, a first air layer is provided between the outercircumferential surface of the cylinder part and the first lightdiffusing surface, and a second air layer is provided between inner andouter circumferential surfaces of the cylinder part.

[4] The light guide described in one of the articles [1] through [3],wherein the hollow part comprises a diffusion region inclined so as toapproach the axis, from the first light diffusing surface toward thelight emitting surface.

[5] The light guide described in one of the foregoing articles [1]through [4], wherein the total reflection surface comprises a finiteregion which surrounds the hollow part and is inclined so as to approachthe axis as a distance from the incident plane increases throughout thefinite region.

[6] The light guide described in one of the foregoing articles [1]through [5], wherein the total reflection surface has a shape which iscurved so as to widen in a direction perpendicular to the axis, and theincident plane is curved so as to be recessed toward the hollow part.

[7] The light guide described in one of the foregoing articles [1]through [5], wherein,

where a distance from the first light diffusing surface to the axisalong the direction perpendicular to the axis is R₁, a maximum distancefrom the total reflection surface including the first light diffusingsurface to the axis along the direction perpendicular to the axis is R₂,a length of the first light diffusing surface along the axial directionof the axis along the first light diffusing surface is L, and

a critical angle of total reflection of the light guide is θ_(C), thefirst light diffusing surface satisfies an expression ofL≧2(R ₂ −R ₁)tan θ_(C,)   (19)and,

where a refractive index of the light guide member is n, the criticalangle θ_(C) of the light guide satisfies an expression of

$\begin{matrix}{\theta_{C} = {{\sin^{- 1}\left( \frac{1}{n} \right)}.}} & (20)\end{matrix}$

[8] The light guide described in the foregoing article [7], wherein,where the light guide is cut along a plane including the axis, the totalreflection surface includes a finite region having a shape in which anangle defined between a normal vector extending from an arbitrary pointon the total reflection surface toward the axis and a vector extendingtoward an outer edge of the light emitting surface is not smaller thanthe critical angle θ_(C).

[9] The light guide described in one of the foregoing articles [1]through [8], wherein the first light diffusing surface has a tip endpositioned in a side opposite to the incident plane along the axialdirection of the axis, and,

where the light guide is cut along the plane including the axis and adistance from a peripheral edge of the light emitting surface to theaxis along the direction perpendicular to the axis is R₃, a distance Hfrom the tip end of the first light diffusing surface to the lightemitting surface along the axial direction of the axis satisfies anexpression ofH≧(2R ₂ +R ₃ −R ₁)tan θ_(C)  (21)

[10] The light guide described in the foregoing article [9], wherein,where a light emission area of the light emitting surface is C, thedistance R3 satisfies an expression of

$\begin{matrix}{R_{3} = {\sqrt{\frac{C}{\pi}}.}} & (22)\end{matrix}$

[11] The light guide described in the foregoing article [6], wherein,

where

-   -   the light guide is cut along a plane including the axis,    -   an intersection point of a line segment intersecting the axis is        taken as an origin point, the line segment being perpendicular        to the axis and extending from the outer peripheral edge of the        incident plane,    -   a direction in which light is emitted from the origin point        along the axis is a direction z,    -   a direction perpendicular to the direction z and extending from        the origin point along the light emitting surface is a direction        x,    -   a distance to an arbitrary point on the incident plane from a        point on an x-axis, which is closest to a peripheral edge of the        light emitting surface, is 1, and    -   a distance from the peripheral edge of the light emitting        surface to the axis along the direction perpendicular to the        axis is R₃,

the total reflection surface of the light guide member is defined by anexpression ofx=lexp(tan θ_(a)Θ)cos Θ−R ₃z=lexp(tan θ_(a)Θ)sin Θ  (23),

a parameter Θ is a finite region included in a range of

$\begin{matrix}{{0 \leq \Theta \leq \frac{\pi}{2}},} & (24)\end{matrix}$

a real constant θ_(a) satisfies an expression of,

$\begin{matrix}{{\theta_{C} < \theta_{a} < \frac{\pi}{2}},} & (25)\end{matrix}$and

a real constant l isl≧2R ₃  (26).

[12] The light guide described in one of the foregoing articles [1]through [7], wherein where a length of the first light diffusing surfacealong the axial direction of the axis is L, the length L satisfies

$\begin{matrix}{1 \leq \frac{L}{2\left( {R_{2} - R_{1}} \right)\tan\;\theta_{C}} \leq 16.} & (27)\end{matrix}$

The invention claimed is:
 1. A lighting apparatus, comprising: a lightsource which comprises a light emitting surface configured to emit lightplanarly by using a semiconductor light emitting device; and a lightguide member which extends through a centroid of the light emittingsurface and is provided to be coaxial with an axis along an axialdirection perpendicular to the light emitting surface, and allows thelight of the light source to penetrate, wherein the light guide membercomprises: an incident plane facing the light emitting surface, an outercircumferential surface which is extended from an outer peripheral edgeof the incident plane in the axial direction so as to surround the axis,and is configured to totally reflect the light of the light source whichis made to enter the light guide member from the incident plane, and ahollow part which is provided at a position distant from the incidentplane along the axial direction and is provided inside the outercircumferential surface, wherein a circumferential surface of the hollowpart extending in the axial direction is a first light diffusing surfaceto which the light totally reflected on the outer circumferentialsurface is led.
 2. The lighting apparatus according to claim 1, whereinthe light guide member has a shape which extends in the axial directionand is rotationally symmetrical about the axis.
 3. The lightingapparatus according to claim 1, wherein the light guide member furthercomprises a light diffuser provided in the hollow part.
 4. The lightingapparatus according to claim 3, wherein the light diffuser has a secondlight diffusing surface which faces the first light diffusing surface ofthe light guide member.
 5. The lighting apparatus according to claim 4,wherein an air layer is provided between the first light diffusingsurface and the second light diffusing surface.
 6. The lightingapparatus according to claim 3, wherein the light diffuser comprises asolid post part and a cylinder part which surrounds the solid post part,a first air layer is provided between the outer circumferential surfaceof the cylinder part and the first light diffusing surface, and a secondair layer is provided between the inner circumferential surfaces of thecylinder part and the outer circumferential surfaces of the solid postpart.
 7. The lighting apparatus according to claim 1, wherein the firstlight diffusing surface is included inside the light guide member. 8.The lighting apparatus according to claim 1, wherein the hollow partincludes a diffusion region which is inclined so as to approach theaxis, from the first light diffusing surface toward the light emittingsurface.
 9. The lighting apparatus according to claim 1, wherein theouter circumferential surface of the light guide member comprises afinite region which surrounds the hollow part and is inclined so as toapproach the axis as a distance from the light source increasesthroughout the finite region.
 10. The lighting apparatus according toclaim 1, wherein the outer circumferential surface of the light guidemember has a shape which is curved so as to widen in a directionperpendicular to the axis, and the incident plane is curved so as to berecessed toward the hollow part.
 11. The lighting apparatus according toclaim 1, further comprising a globe which covers the light guide member.12. The lighting apparatus according to claim 11, wherein the hollowpart including the first light diffusing surface is positioned in acentral part of the globe.
 13. The lighting apparatus according to claim10, wherein where a distance from the first light diffusing surface tothe axis along the direction perpendicular to the axis is R₁, a maximumdistance from the outer circumferential surface including the firstlight diffusing surface to the axis along the direction perpendicular tothe axis is R₂, a length of the first light diffusing surface along theaxial direction of the axis is L, and a critical angle of totalreflection of the light guide member is θ_(C), the first light diffusingsurface satisfies an expression ofL≧2(R ₂ −R ₁)tan θ_(C,)   (2) and where a refractive index of the lightguide member is n, a critical angle θ_(C) of the light guide membersatisfies an expression of $\begin{matrix}{\theta_{C} = {{\sin^{- 1}\left( \frac{1}{n} \right)}.}} & (1)\end{matrix}$
 14. The lighting apparatus according to claim 13, whereinwhere the light guide member is cut along a plane including the axis,the outer circumferential surface of the light guide member includes ashape in which an angle defined between a normal vector extending froman arbitrary point on the outer circumferential surface toward the axisand a vector extending toward an outer edge of the light emittingsurface is not smaller than a critical angle θ_(C).
 15. The lightingapparatus according to claim 14, wherein the point on the outercircumferential surface includes a point at which the normal vectorintersects, at right angles, the axis and the distance to the axis ismaximized.
 16. The lighting apparatus according to claim 1, wherein thefirst light diffusing surface of the light guide member has a tip endpositioned in a side opposite to the incident plane along the axialdirection of the axis, and, where the light guide member is cut along aplane including the axis and a distance from a point on a peripheraledge of the light emitting surface to the axis along a directionperpendicular to the axis is R₃, a distance H from the tip end of thefirst light diffusing surface to the light emitting surface along theaxial direction of the axis satisfies an expression ofH≧(2R ₂ +R ₃ −R ₁)tan θ_(C)  (4).
 17. The lighting apparatus accordingto claim 16, wherein, where a light emission area of the light emittingsurface is C, the distance R₃ satisfies an expression of $\begin{matrix}{R_{3} = {\sqrt{\frac{C}{\pi\;}}.}} & (5)\end{matrix}$
 18. The lighting apparatus according to claim 10, wherein,where the light guide member is cut along a plane including the axis, anintersection point of a line segment intersecting the axis is taken asan origin point, the line segment being perpendicular to the axis andextending from the outer peripheral edge of the incident plane, adirection in which light is emitted from the origin point along the axisis a direction z, a direction perpendicular to the direction z andextending from the origin point along the light emitting surface is adirection x, a distance to an arbitrary point on the incident plane froma point on an x-axis, which is closest to a peripheral edge of the lightemitting surface, is 1, and a distance from the peripheral edge of thelight emitting surface to the axis along the direction perpendicular tothe axis is R₃, the outer circumferential surface of the light guidemember is defined by an expression ofx=lexp(tan θ_(a)Θ)cos Θ−R ₃z=lexp(tan θ_(a)Θ)sin Θ  (23), a parameter Θ is a finite region includedin a range of $\begin{matrix}{{0 \leq \Theta \leq \frac{\pi}{2}},} & (24)\end{matrix}$ a real constant θ_(a) satisfies an expression of,$\begin{matrix}{{\theta_{C} \leq \theta_{a} < \frac{\pi}{2}},} & (25)\end{matrix}$ and a real constant 1 isl≧2R ₃  (26).
 19. A lighting apparatus, comprising: a light source whichcomprises a semiconductor light emitting element and a light emittingsurface configured to emit light; and a light guide member providedcoaxially with an axis extending along an axial direction perpendicularto the light emitting surface, the light guide member configured toallow the light of the light source to penetrate, wherein the lightguide member comprises: an incident plane facing the light emittingsurface, an outer circumferential surface which is extended from anouter peripheral edge of the incident plane in the axial direction so asto surround the axis, and is configured to totally reflect the lightwhich is made to enter the light guide member from the incident plane,and a hollow part which is provided at a position distant from theincident plane along the axial direction and is provided inside theouter circumferential surface, and comprises a first light diffusionsurface extending in the axial direction to which the light totallyreflected on the outer circumferential surface is led; where a length ofthe first light diffusing surface along the axial direction is L, thelight guide member satisfies an expression of $\begin{matrix}{1 \leq \frac{L}{2\left( {R_{2} - R_{1}} \right)\tan\;\theta_{C}} \leq 16.} & (27)\end{matrix}$ a distance from the first light diffusing surface to theaxis along the direction perpendicular to the axis is R₁, a maximumdistance from the outer circumferential surface including the firstlight diffusing surface to the axis along the direction perpendicular tothe axis is R₂, a critical angle of total reflection of the light guidemember is θ_(C).
 20. A light guide which is provided to be coaxial withan axis extending through a centroid of the light emitting surface alongan axial direction and being perpendicular to a light emitting surface,and allows light emitted from the light emitting surface to penetrate,comprising: an incident plane facing the light emitting surface; a totalreflection surface which is extended from an outer peripheral edge ofthe incident plane in the axial direction extending away from the lightemitting surface so as to surround the axis, and is configured tototally reflect the light which is made to enter the light guide fromthe incident plane, and a hollow part which is provided at a positiondistant from the incident plane along the axial direction and isprovided inside the total reflection surface, wherein a circumferentialsurface of the hollow part extending in the axial direction is a firstlight diffusing surface to which the light totally reflected on thetotal reflection surface is led.